Agricultural trench depth sensing systems, methods, and apparatus

ABSTRACT

An agricultural trench depth sensing system having a trench implement adapted to be disposed in a soil trench opened in a soil surface. In one embodiment an ultrasonic sensor detects a distance to an upper surface of said trench implement or a target disposed thereon. In another embodiment, said trench implement includes one or more fingers which rotate with respect to said trench implement to detect the soil surface relative to said trench implement. In another embodiment, said trench implement includes side sensors for detecting the sidewall of the soil trench.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional application of U.S. application Ser.No. 16/254,247, filed 22 Jan. 2019, which is a continuation ofInternational Application No. PCT/US2017/043565, filed 24 Jul. 2017,which claims the benefit of U.S. Provisional Application No. 62/365,585filed Jul. 22, 2016, and U.S. Provisional Application No. 62/491,707,filed Apr. 28, 2017, all of which are incorporated herein in theirentireties by reference.

BACKGROUND

In recent years, farmers have recognized the need to select and maintainthe proper planting depth to ensure the proper seed environment (e.g.,temperature and moisture) and seedling emergence. To improve agronomicpractices, it would also be desirable for the farmer to understand therelationship between actual planting depth and metrics such as emergenceand yield. Conventional agricultural planters include only apparatus foradjusting a maximum planting depth, which may not be maintained duringoperation due to soil conditions or insufficient downpressure on theplanter row unit. Disclosed in U.S. Patent Publication NumberUS2015/0289438 is a depth sensor with a pivot arm having left and rightground engaging fingers, wherein the pivot arm is pivotably connected toan angular displacement sensor mounted to a bracket on a row unit or toa seed firmer. The ground engaging fingers engage the soil surface oneither side of the seed trench. As the depth of the seed trench changes,the pivot arm rotates causing a signal change in the angulardisplacement sensor. While this system provides a good measurement, itis desirable to increase the accuracy and/or durability of the system.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a right side elevation view of an embodiment of anagricultural row unit.

FIG. 2 is a right side elevation view of another embodiment of anagricultural row unit with certain components removed for clarity.

FIG. 3 is a perspective view of the agricultural row unit of FIG. 2 .

FIG. 4 is a perspective view of the agricultural row unit of FIG. 2 witha right gauge wheel removed for clarity.

FIG. 5 is an enlarged partial right side elevation view of theagricultural row unit of FIG. 2 .

FIG. 6 is a rear elevation view of the agricultural row unit of FIG. 5 .

FIG. 7A is an elevation view of an embodiment of a seed firmer having anultrasonic target.

FIG. 7B is an elevation view of an embodiment of a seed firmer having anultrasonic transmitter aimed at a target mounted to a row unit.

FIG. 7C is an elevation view of an embodiment of a seed firmer withoutan ultrasonic target in use with an ultrasonic transmitter mounted to arow unit.

FIG. 8 is a partial perspective view of an embodiment of a seed firmerhaving an ultrasonic target disposed on a top surface of the seedfirmer.

FIG. 9 is a representative illustration of signals generated by anultrasonic sensor.

FIGS. 10A-10C are top plan views showing different embodiments of seedfirmers with ultrasonic sensors.

FIG. 11A is a perspective view of an embodiment of a seed firmer withultrasonic transceivers supported on a transverse arm above the seedfirmer.

FIG. 11B is an elevation view of the seed firmer of FIG. 11A shown in aseed trench with the finger sensors disposed on each side of the seedtrench.

FIG. 11C is a perspective view of an embodiment of a seed firmer withultrasonic transceivers supported on a transverse arm above the seedfirmer and mounted to the row unit.

FIG. 12A-1 is a perspective view of a seed firmer with a firstembodiment of finger sensor.

FIG. 12A-2 is an elevation view of the seed firmer of FIG. 12A-1 shownin a seed trench with the finger sensors disposed on each side of theseed trench.

FIG. 12B-12F are perspective views of a seed firmer with alternativeembodiments of finger sensors.

FIG. 13A is a perspective view of an embodiment of a seed firmer withside sensors.

FIG. 13B is an elevation view of the seed firmer of FIG. 13A shown in aseed trench.

FIG. 13C is a perspective view of an embodiment of a seed firmer withside sensors disposed in a wall that is biased toward a sidewall of aseed trench.

FIG. 13D is a top plan view of the seed firmer embodiment of FIG. 13C.

FIG. 13E is a perspective view of another embodiment of a seed firmerwith side sensors similar to FIG. 13C but with the wall attach to thebottom of the seed firmer.

FIG. 13F is a perspective view of another embodiment of a seed firmerwith side sensors disposed in a convex wall that is biased toward asidewall of a seed trench.

FIG. 13G is a top plan view of the seed firmer embodiment of FIG. 13F.

FIG. 14 schematically illustrates an embodiment of a depth sensor systeminstalled on a tractor and planter.

FIG. 15 is an embodiment of an accelerometer disposed on a depthadjustment body or gauge wheel arm.

FIG. 16 is embodiment of an accelerometer disposed on a depth adjustmentassembly.

FIG. 17 illustrates a process for controlling trench depth.

DETAILED DESCRIPTION

Referring to the drawings, wherein like reference numerals designateidentical or corresponding parts throughout the several views, FIG. 1illustrates an embodiment of an agricultural implement, e.g., a planter,comprising a toolbar 8 to which multiple row units 10 are mounted intransversely spaced relation. In the embodiment shown, each row unit 10is mounted to the toolbar by a parallel arm arrangement 16 such that therow unit is permitted to translate vertically with respect to thetoolbar. An actuator 18 is pivotally mounted to the toolbar 8 and theparallel arm arrangement 16 and is configured to apply supplementaldownpressure to the row unit 10.

The row unit 10 includes a frame 14 which supports an opening discassembly 60, a gauge wheel assembly 50 and a closing assembly 40. Theopening disc assembly 60 includes two angled opening discs 62 rollinglymounted to a downwardly extending shank 15 of the frame 14. The openingdiscs 62 are disposed to open a v-shaped seed trench 3 in the soilsurface 7 as the row unit advances forwardly through the field. Thegauge wheel assembly 50 includes two gauge wheels 52 pivotally mountedto either side of the frame 14 by two gauge wheel arms 54 with the gaugewheels 52 disposed to roll along the soil surface 7. A depth adjustmentassembly 90 is pivotally mounted to the frame 14 at a pivot 92. Thedepth adjustment assembly 90 engages with the gauge wheel arms 54 tolimit the upward travel of the gauge wheel arms 54, thus limiting thedepth of the trench opened by the opening disc assembly 60. The closingassembly 40 is pivotally coupled to the frame 14 and is configured tomove soil back into the seed trench 3.

Continuing to refer to FIG. 1 , seeds 5 are communicated from a hopper12 to a seed meter 30 configured to singulate the supplied seeds. Theseed meter 30 may be a vacuum-type meter such as that disclosed inInternational Publication No. WO2012/129442 or any other seed meterknown in the art. In operation, the seed meter 30 dispenses singulatedseeds into the seed tube 32 which communicates the singulated seedsdownwardly and rearwardly before depositing the seeds into the seedtrench 3.

Turning to FIGS. 2-6 , the depth adjustment assembly 90 is illustratedin more detail. The depth adjustment assembly 90 includes a rocker 95(FIGS. 4-5 ) pivotally mounted to a depth adjustment body 94. The depthadjustment body 94 is pivotally mounted to the row unit frame 14 aboutthe pivot 92. A handle 98 is preferably slidably received within thedepth adjustment body 94 such that the user can selectively engage anddisengage the handle with one of a plurality of depth adjustment slots97 (FIG. 6 ) formed within the row unit frame 14. In operation, theupward travel of the gauge wheels 52 is limited by contact of the gaugewheel arms 54 with the rocker 95. When one of the gauge wheels, e.g.,left gauge wheel 52-1, encounters an obstruction, the rocker 95 allowsthe left gauge wheel arm 54-1 to travel upward while lowering the rightgauge wheel 52-2 by the same absolute displacement such that the rowunit 10 rises by half the height of the obstruction.

Depth Sensing Implements

The various agricultural trench depth sensing implements 100 describedbelow and illustrated herein utilize a seed firmer for simplicity of thedescription and because the seed firmer is already an existing implementthat is placed in a seed trench. However, the agricultural trench depthsensing implement 100, may utilize any tool or structure that is capableof being disposed in a soil trench opened in a soil surface formeasuring depth of the soil trench. Additionally, although theagricultural trench depth sensing implements 100 are illustrated anddescribed in connection with a seed trench formed by a planter row unit,the depth sensing implement 100 may be disposed in any trench opened ina soil surface by any implement, assembly or tool. Accordingly, thetrench in which the depth sensing implement 100 is disposed may bereferred to interchangeably as a soil trench or seed trench.

Ultrasonic Sensor Embodiments

In one embodiment of the agricultural trench depth sensing implement 100shown in FIG. 7A, a seed firmer 99, similar to the seed firmerembodiments disclosed in U.S. Pat. No. 5,425,318, is provided with anultrasonic target 710 disposed on the top side of a rigid portion of theseed firmer 99. The rigid portion of the seed firmer is anyplace inwhich a point on top of the seed firmer remains relative to a point atthe rearward or trailing end of the seed firmer. In FIG. 7 , for theseed firmer shown, the rigid portion is anywhere between A and B on seedfirmer 99. Seed firmer 99 may be mounted to row unit 10 as recognized bythose of skill in the art.

In another embodiment of the depth sensing implement 100 shown in FIG.7B, seed firmer 99 is provided with an ultrasonic transmitter 720mounted on the top side of a rigid portion of the seed firmer 99. Anultrasonic target 710 may be mounted (such as by an arm 711) to the rowunit 10 and aimed at seed firmer 99 to receive an ultrasonic signal fromthe ultrasonic transmitter 720. The purpose of providing an ultrasonictarget 710 is for returning an ultrasonic signal to an ultrasonictransmitter or for receiving an ultrasonic signal.

The ultrasonic transmitter and the ultrasonic receiver may be combinedas a transceiver. At least one ultrasonic sensor may be used inconjunction with seed firmer 99.

The ultrasonic target 710 may have a unique shape to return a uniquesignal back to the ultrasonic sensor. Referring to FIG. 8 , oneembodiment providing a unique shape is a stepped block 810 having threedifferent step heights. With the ultrasonic target 710 comprising astepped block 810 the signal generated and returned will initially be anarea of high amplitude as the signal is first generated, then there willbe a period of low amplitude before three areas of amplitude will beobserved corresponding to each height on the step block 810 with aspacing between each block's return signal. The step block 810 providesa signature signal 910 that can be used for measuring depth. FIG. 9 is arepresentative illustration of the signature 910 of a return signal forultrasonic sensor 710 having three different levels.

In another embodiment of the depth sensing implement 100 shown in FIG.7C, a depth sensing system is provided with a seed firmer 99 without anultrasonic target 710. In this embodiment, ultrasonic sensor 1010measures the distance to the top of seed firmer 99 directly with theultrasonic sensor 1010 mounted to row unit 10 (such as by an arm 1011)and aimed at seed firmer 99.

Referring to FIGS. 10A-10C, which are top plan views of the embodimentsof FIGS. 7A-7C, respectively, there can additionally be a pair ofultrasonic sensors (1020-1, 1020-2) disposed on the row unit 10 with oneaimed at soil surface 7-1 adjacent to one side of the soil trench 3 andthe other aimed at soil surface 7-2 adjacent to the other side of thesoil trench 3. In FIG. 10A, the ultrasonic target 710 is disposed on thetop side of the seed firmer 99 and the transmitter/transceiver 720disposed on the row unit 10 supported therefrom by arm 711. In FIG. 10B,the transmitter/transceiver 720 is disposed on the top side of the seedfirmer 99 and the ultrasonic target 710 is disposed on the row unit 10supported therefrom by arm 711. In FIG. 10C, the transceiver 1010 isdisposed on the row unit 10 supported therefrom by arm 1011 without atarget on the seed firmer 99. By providing the pair of ultrasonicsensors 1020-1, 1020-2 on each side of the soil trench 3 in conjunctionwith the ultrasonic sensor disposed on or over the seed firmer, threemeasurements are provided which may be used to determine depth of thesoil trench 3. The measurements from each side can be averaged orweighted to provide a single measurement for reference for the soilsurface. This can be useful when there is debris as described below. Thedifference between the measurement for soil surfaces 7-1 and/or 7-2 toseed firmer 99 can be used to determine the depth of the soil trench 3.

In any of the above embodiments of the depth sensing implement 100,there is an expected range of distance between a transmitted ultrasonicsignal and the object that is being targeted. There may debris, such asa rock, a clump of dirt, or a plant stalk, next to the soil trench 3which will shorten the measured distance. In the case of a plant stalk,the plant stalk may lean over the soil trench 3 and come between theultrasonic signal to or from seed firmer 99. When a signal is receivedthat translates to a distance outside of an expected range, the data forthis measurement may be discarded to prevent an unrealistic measurementfrom being used.

It should be appreciated that gauge wheels 52 or wheels on closingassembly 40 may cause a divit near the sides of the soil trench 3. Whenmeasuring the distance to the ground, this divit distance may beaccounted for when mounting the sensors 1020-1, 1020-2 on the row unit10.

In any of the embodiments above, a plurality of measurements for a givenlocation may be taken and averaged. For example, three measurements fora given location may be taken and averaged.

FIG. 11A shows another embodiment of depth sensing implement 100comprising a seed firmer 99 with a mounting arm 1160 mounted to therigid portion of seed firmer 99 and capable of rising above the seedfirmer 99. The mounting arm 1160 supports a transverse portion 1170perpendicular to seed firmer 99 and sized so that the outer ends of thetransverse portion 1170 extend over adjacent sides of trench 7-1 and7-2. Ultrasonic transceivers 1120-1 and 1120-1 are disposed near theouter ends of the transverse portion 1170 and are aimed down to adjacentsides 7-1 and 7-2 of the soil trench 3. Knowing the placement of seedfirmer 99, ultrasonic transceivers 1120-1 and 1120-2 measure thedistance to the adjacent sides of trench 7-1 and 7-2 so that the seeddepth in seed trench 3 may be calculated. Alternatively, only onetransceiver 1120-1 or 1120-2 may need to be used, but having both allowsfor better measurement and accounting for debris. This embodimentsimplifies over the embodiments described below in connection with FIGS.12A to 12C by eliminating one measurement.

FIG. 11C shows another embodiment of a depth sensing implement 100similar to the embodiment shown in FIG. 11A, except that mounting arm1160-1 is disposed on row unit 10. Knowing the placement of seed firmer99, ultrasonic transceivers 1120-1 and 1120-2 measure the distance tothe adjacent sides of trench 7-1 and 7-2 so that the seed depth intrench 3 can be calculated. Also, only one ultrasonic transceiver 1120-1or 1120-2 may need to be used, but having both allows for bettermeasurement and accounting for debris.

Finger Sensor Embodiments

FIGS. 12A-12F illustrate various embodiments a depth sensing implement100 comprising a seed firmer 99 to which is coupled a first groundengaging finger 1210 and a second ground engaging finger 1220 whereinthe first ground engaging finger 1210 contacts soil surface 7-1 adjacentsoil trench 3, and the second ground engaging finger 1220 contacts soilsurface 7-2 adjacent soil trench 3.

In a first embodiment shown in FIG. 12A-1 , each ground engaging finger1210 and 1220 is disposed on seed firmer 99 independent from the otherground engaging finger. Each ground engaging finger 1210, 1220 ispivotally mounted to brackets 1230-1 and 1230-2 that are disposed on therigid portion of seed firmer 99 that allows for rotation of the groundengaging finger 1210 and 1220 in a vertical direction. To measure thedistance that each ground engaging finger 1210 and 1220 travels relativeto seed firmer 99, bracket 1230-1 and 1230-2 each have a rotary encoder1240-1 and 1240-2 (such as angular displacement sensor no. 55250available from Hamlin Incorporated, Lake Mills, Wis.). In operation, theground engaging fingers 1210 and 1220 ride along the soil surface 7-1,7-2 (see FIG. 12A-2 ) such that the angular position of the groundengaging finger 1210 and 1220 is constrained relative to the soilsurface. A signal generated by the encoders 1240-1 and 1240-2 is thusrelated to the vertical height of the row unit 10 with respect to thesoil, and thus to the depth of the soil trench 3.

In an alternative embodiment shown in FIG. 12B, the ground engagingfingers 1210 and 1220 are pivotally mounted to brackets 1230-1 and1230-2, but instead of the rotary encoder 1240-1 and 1240-2 (as in FIG.12A), in the embodiment of FIG. 12B, Hall effect sensors 1250-1 and1250-2 are disposed on or in seed firmer 99 for detecting a position ofthe ground engaging fingers 1210 and 1220. In either of the embodimentsshown in FIG. 12A or 12B, rather than two brackets 1230-1, 1230-2, theremay be a single bracket 1230, such as shown in FIG. 12C.

FIG. 12D illustrates yet another alternative embodiment of a depthsensing implement 100 apparatus utilizing finger sensors. In thisembodiment, ground engaging fingers 1210 and 1220 are connected togetherthrough an arm 1260 pivotally connected at its distal end to a bracket1230. The arm 1260 pivots or rotates about a pivot axis of the bracket1230 in a vertical direction above seed firmer 99 to allow groundengaging fingers 1210 and 1220 to raise and lower to engage soil surface7-1 and 7-2, respectively. A Hall effect sensor 1250 is disposed on orin seed firmer 99 or on or in the arm 1260 for detecting the position ofthe arm 1260 relative.

In another embodiment shown in FIG. 12E, ground engaging fingers 1210and 1220 are connected through an angular displacement sensor 1270allowing for rotation around seed firmer 99. The angular displacementsensor 1270 is connected through an arm 1260 that is pivotally mountedto a bracket 1230 disposed on the rigid portion of seed firmer 99 suchthat the arm 1260 is able to pivot or rotate about a pivot axis throughthe bracket 1230 in a vertical direction. This configuration allows forone or both ground engaging fingers 1210 and 1220 to engage soil surface7-1 and 7-2, respectively. Arm 1260 will pivot in a vertical directionabove seed firmer 99, and ground engaging fingers 1210 and 1220 will beable to rotate around seed firmer 99 to the lowest point. In the eventthat one ground engaging finger 1210 or 1220 encounters debris, such asa rock, a clump of dirt, or a stalk, the other ground engaging fingerwill still be able to rotate towards the soil surface 7. This allows forbetter exclusion of data samples that are out of the expected range.Thus, it should be appreciated that if the ground engaging fingers 1210and 1220 are in fixed relationship to each other, any debris will causeboth ground engaging fingers 1210 and 1220 to be at the same verticalheight over seed firmer 99. However, with angular displacement sensor1240 as shown in FIG. 12E, when measuring the height displacement of arm1260, angular displacement sensor 1270 can allow for detection of debrisand correction of the height based on the rotation of angulardisplacement sensor 1270.

In another embodiment shown in FIG. 12F, which is similar to theprevious embodiment shown in FIG. 12E, ground engaging fingers 1210 and1220 are connected through a pivot 1280 allowing for rotation aroundseed firmer 99. The arm 1265 supports the pivot 1280 at its rearward endand the forward end of the arm 1265 is pivotable about pin 1240 withinthe bracket 1230 disposed on the rigid portion of seed firmer 99 thusallowing for the rotation of arm 1265 in a vertical direction. Thisconfiguration allows for one or both ground engaging fingers 1210 and1220 to engage soil surface 7-1 and 7-2, respectively. Arm 1265 willpivot in a vertical direction above seed firmer 99, and ground engagingfingers 1210 and 1220 will be able to rotate around seed firmer 99 tothe lowest point. In the event that one ground engaging finger 1210 or1220 encounters debris, such as a rock, a clump of dirt, or a stalk, theother ground engaging finger will still be able to rotate towards thesoil surface 7 and thus have angular displacement sensor travel abouthalf of the distance if the pivot 1280 were not present. This allows forbetter exclusion of data samples that are out of the expected range.When both ground engaging fingers 1210 and 1220 are in fixedrelationship to each other, any debris causes both ground engagingfingers 1210 and 1220 to be at the same vertical height over seed firmer99.

Side Sensor Embodiments

FIGS. 13A-13F illustrate various alternative embodiments of a trenchdepth sensing implement 100 which utilize a seed firmer 99 with sidesensors 1310. Each of the side sensors are in electrical communicationwith a processor 120 (discussed below). In the embodiment illustrated inFIG. 13A, seed firmer 99 has a plurality of sensors 1310 disposed invertical alignment on the side of seed firmer 99 at a rigid portion forsensing the presence of soil in the soil trench 3. The rigid portion ofthe seed firmer 99 on which the sensors 1310 are disposed may have aheight greater than the depth of the soil trench 3 such that least oneof the sensors 1310 is above the soil surface 7 in order to detect thetop of the soil trench 3. It should be appreciated that if seed firmer99 does not have a sufficient height, then all sensors 1310 would be inthe trench 3 and the top of the trench 3 could not be determined.Alternatively, rather than rigid portion of the seed firmer having aheight greater than the depth of the soil trench, the sensors 1310 maybe disposed in the rigid portion section of the seed firmer 99 towardthe forward end (i.e., opposite the rearward or trailing end 98 of theseed firmer 99) where the seed firmer curves upward towards theattachment end 97 above the soil trench 3 such that at least one of thesensors 1310 is above the top of soil trench 3.

FIG. 13C illustrates another embodiment of a trench depth sensingimplement 100 in which side sensors 1310 are disposed on a wall 1320that diverges outwardly from the body of the seed firmer 99 andrearwardly away from the forward resilient portion 1340 of the seedfirmer 99 such that at least some of the side sensors 1310 are incontact with the sidewall of the soil trench 3. As illustrated in FIG.13D, a biasing element 1350, such as a spring, may be disposed betweenseed firmer 99 and wall 1320 to bias the wall 1320 outwardly toward thesidewall of the soil trench 3. Illustrated in FIG. 13E is anotherembodiment in which the bottom 1321 of wall 1320 is connected at thebottom 1322 of seed firmer 99 such that the wall 1320 diverges outwardlyupwardly from the bottom 1322 of the seed firmer 99.

In another embodiment illustrated in FIG. 13F, the sensors 1310 aredisposed on an arcuate wall 1330 which diverges outwardly from the bodyof the seed firmer 99 and rearwardly away from the forward resilientportion 1340 of the seed firmer 99 before curving back toward the seedfirmer body. In this embodiment, the forward end, the rearward end aswell as the upper end and bottom end of the arcuate wall 1330 areconnected to the body of the seed firmer 99. The arcuate wall 1330 maybe biased away from the body of the seed firmer 99 towards a sidewall ofthe trench, such as by a spring 1350 disposed between the body of theseed firmer 99 and the arcuate wall 1330.

It should be appreciated that the more sensors 1310 disposed on the seedfirmer 99 or on the walls 1320, 1330 will allow for an increasedfineness of measurement of the depth of the soil trench 3. In thevarious embodiments, there may be at least three sensors 1310 or atleast four, at least five, at least six, at least seven, at least eight,at least nine, or at least ten sensors 1310.

The sensors 1310 may be any sensor that can sense soil in the side ofthe soil trench 3. These can include, but are not limited to, optical,capacitance, inductive, radar, or ultrasonic. The depth of the soiltrench 3 may be determined by knowing the relative position of the seedfirmer 99 on row unit 10 in relation to the bottom of seed firmer 99such that the change between sensors indicating a difference betweensoil and above the trench. The location of these sensors is then usedfor determining depth. It should be appreciated that soil trenches aretypically V-shaped. Thus, depending on the embodiment, sensors 1310 atthe bottom of seed firmer 99 may be closer to the soil defining thesidewalls of the soil trench than the sensors 1310 at the top of seedfirmer 99. The difference in signal may be taken into consideration fordetermining the top of trench 3.

As stated previously, although the embodiments above are described andillustrated with a seed firmer 99 that is typically used when plantingand which is disposed in the seed trench 3, it will be appreciated thatseed firmer 99 may be replaced with any other implement that can beattached to a planter row unit 10 or other agricultural implement. Withrespect to planter row units, the depth being measured is the depthwhere seed 5 is in the seed trench 3. Seed trenches are typically formedas a V-shape by opening discs 62, and because of the size and/or shapeof seed 5, the seed 5 may not be fully at the bottom of trench 3. Thusfor planter applications, it may be more important to determine theactual depth of seed 5 and not the total depth of the seed trench 3. Insuch applications, because the bottom of seed firmer 99 contacts the topof seed 5, knowing the location of seed firmer 99 allows for knowing thedepth of the seed 5.

Accelerometer

In another embodiment, an accelerometer 700 may be disposed on any partthat adjusts when depth is adjusted. Parts that adjust when depth isadjusted include gauge wheel arm 54, depth adjustment body 94, or adepth adjustment assembly 90. Examples of depth adjustment assembliesare described in PCT Application No. PCT/US2017/018269, which isincorporated herein by reference in its entirety. Each of the parts thatadjust when depth is adjusted have a range of motion that is related toa position of the gauge wheel 52, which translates to gauge wheel arm52, depth adjustment body 94, and depth adjustment assembly 90, whichthus relates to depth of the soil trench. As the position of any ofthese parts on which the accelerometer is disposed changes positionacross its range of motion, the orientation of accelerometer 700changes. The change in orientation of accelerometer 700 relates to theposition of the part, which provides the depth of the soil trench 3. Inone embodiment, accelerometer 700 is positioned so that none of itsx-axis, y-axis, or z-axis are perpendicular to the ground across theentire range of motion of the part. This allows all three axes to beused to determine position across the full range of motion. FIG. 15illustrates accelerometer 700 disposed on depth adjustment body 94 orgauge wheel arm 54-2. Both placements are used for illustration purposesin a single drawing, but only one accelerometer 700 is required. FIG. 16illustrates accelerometer 700 disposed on an embodiment of depthadjustment assembly 90 providing automatic depth control (discussedbelow).

Automatic Trench Depth Adjustment

A trench depth adjustment system 500 for automatically controlling thedepth of the soil trench 3 is illustrated in FIG. 14 . The trench depthsensor implement 100 (representing any of the above sensors) mounted toeach row unit 10 is in communication (electrical or wireless) with aprocessor 120. The processor 120 may be disposed in the trench depthsensing implement 100, on the row unit 10, or incorporated into themonitor 540 (as shown in FIG. 14 ) located in the cab 80 of a tractordrawing the planter. The monitor 540 is in electrical communication witha depth adjusting assembly 90 configured to modify the depth of thetrench 3. The monitor 540 may include a central processing unit, amemory, and a graphical user interface configured to display the depthmeasured by the trench depth sensor implement 100. The monitor 540 mayinclude processing circuitry configured to modify a command signal tothe depth control assembly 90 based on an input from the trench depthsensor implement 100. The command signal preferably corresponds to aselected depth. The monitor 540 may also be in electrical communicationwith a GPS receiver 550 mounted to the tractor or the planter.

A trench depth control system, such as disclosed U.S. Patent ApplicationPublication No. 2013/0104785, incorporated herein in its entirety byreference, may be configured to automatically control the depthadjusting assembly to modify the depth of the trench 3 based on depthmeasured by the trench depth sensor implement 100. FIG. 16 illustratesan alternative embodiment for automatically controlling trench depthbased on depth measured by the trench depth sensor implement 100. Asillustrated in FIG. 16 , and as disclosed in Applicant's InternationalPatent Application No. PCT/US2017/018274, incorporated herein in itsentirety by reference, a depth adjustment assembly 90 utilizes a gearrack 1910 and an electric motor 1930 configured to drive gears 1940along the gear rack 1910. The electric motor 1930 is in electricalcommunication with the monitor 540, which is in communication with anyof the embodiments of the trench depth sensor implements 100 disclosedherein. As discussed in more detail below, when the monitor 540determines that the measured trench depth is not equal to or within athreshold range (e.g., 5%) of a preselected depth, the monitor 540 sendsa command signal to actuate the electric motor 1930 to drive the gears1940 to position the depth adjustment body 1994 with respect to theframe 14 and the gauge wheel arms 54 to produce the measured trenchdepth that approximates the selected trench depth.

The measured trench depth may be mapped by the monitor 540 recording andtime-stamping the GPS position of the planter reported by the GPSreceiver 550 based on the monitor 540 receiving signals from the trenchdepth sensor implements 100 described herein associated with each rowunit. The monitor 540 may store and time-stamp the depth measurements(the “measured depth”) at each row unit. The monitor 540 may display animage correlated to the measured depth on a map at a map locationcorresponding to the GPS position of the planter at the time of thedepth measurements. For example, in some embodiments the monitor 540displays a legend correlating colors to ranges of depth. In some suchembodiments, the depth range less than zero is correlated to a singlecolor while a set of depth ranges greater than zero are correlated to aset of colors such that the color intensity increases with depth.

FIG. 17 illustrates a process 1700 for controlling depth based on thesignal generated by one of the trench depth sensor implements 100described above. At step 1710, the monitor 540 preferably estimates thedepth of the trench 3 based on the signal generated by the trench depthsensor implement 100. At step 1720, the monitor 540 preferably comparesthe measured depth to a selected depth entered by the user or previouslystored in memory. Alternatively, the selected depth may be selectedusing the methods disclosed in U.S. Publication No. US2016/0037709,incorporated herein in its entirety by reference. If at step 1730 themeasured depth is not equal to or within a threshold range (e.g., 5%) ofthe selected depth, then at step 1740 the monitor 540 preferably sends acommand signal to the depth adjuster 90 in order to bring the measureddepth closer to the selected depth; for example, if the measured depthis shallower than the selected depth, then the monitor 540 preferablycommands the depth adjuster to rotate the depth adjustment assembly 90in order to increase the trench depth.

Various modifications to the preferred embodiment of the apparatus, andthe general principles and features of the system and methods describedherein will be readily apparent to those of skill in the art. Thus, thepresent invention is not to be limited to the embodiments of theapparatus, system and methods described above and illustrated in thedrawing figures, but is to be accorded the widest scope consistent withthe scope of the appended claims.

1. An agricultural trench depth sensing system comprising: an implementframe; a trench opener connected to said implement frame, said trenchopener opening a soil trench in a soil surface as said implement frameadvances in a direction of travel; a sensor implement connected to saidimplement frame and disposed in said soil trench rearward from saidtrench opener in said direction of travel, wherein said sensor implementhas a plurality of sensors disposed in vertical alignment on a side ofsaid sensor implement for sensing the presence of soil in said soiltrench; wherein said sensor implement has a height that is taller than adepth of said soil trench in said soil surface; and wherein at least oneof said plurality of sensors is disposed on said sensor implement abovesaid soil trench.
 2. The agricultural trench depth sensing system ofclaim 1, wherein said sensor implement is a seed firmer.
 3. Theagricultural trench depth sensing system of claim 1, wherein saidplurality of sensors are one of an optical, capacitance, inductive,radar, and ultrasonic sensor.
 4. The agricultural trench depth sensingsystem of claim 1, wherein said plurality of sensors are one of anoptical, inductive, radar, and ultrasonic sensor.
 5. The agriculturaltrench depth sensing system of claim 1, wherein said plurality ofsensors are capacitance sensors.
 6. The agricultural trench depthsensing system of claim 1, wherein said side of said sensor implement isa wall attached to a central portion of said sensor implement, and saidwall is biased toward a sidewall of said soil trench away from saidcentral portion.